Method and system for establishing model based on virtual algorithm

ABSTRACT

The present disclosure provides a model establishing method based on a virtual algorithm, comprising: a) simulating a single subpixel; b) simulating a subpixel array of a single color; c) overlaying subpixel arrays of different colors; and d) deriving a virtual signal.

TECHNICAL FIELD

The present invention relates to the display field, and more particularly to a method and system for establishing a model based on a virtual algorithm

BACKGROUND

A virtual algorithm can fully utilize the characteristics of human eyes for spatial resolution to achieve a relatively high virtual resolution with respect to a specific subpixel arrangement under a relatively low physical resolution, by way of subpixel share, etc. It has such advantages as low power consumption, low process difficulty and high resolution, etc.

The core concept of the virtual algorithm is subpixel share. If a pixel position is lack of a subpixel of corresponding color, the way of subpixel share needs to be used to derive virtually the color that the position is lack of. If each derived virtual pixel can restore the input signal accurately, it indicates that this share algorithm can achieve a relatively high virtual resolution by using a relatively low physical resolution.

Some virtual algorithms also have disadvantages, for example, there will emerge colorful sides at image edges (color aliasing effect), and/or there will emerge sawtooth shapes, etc. at slash borders. Therefore it needs to continuously optimize and adjust these algorithms. In order to judge the merits of the algorithm, it needs to establish a set of stable evaluation system. A common practice is to calculate the RMS of the difference between corresponding pixels (as shown in the following formula). The smaller the RMS is, the smaller the difference between the output signal and the input signal is, and the higher the degree of reduction of the algorithm for the original picture is.

$\frac{1}{N}{\sum\limits_{All}\; \sqrt{\left( {R_{out} - R_{i\; n}} \right)^{2} + \left( {G_{out} - G_{i\; n}} \right)^{2} + \left( {B_{out} - B_{i\; n}} \right)^{2}}}$

R_(out), G_(out) and B_(out) represent the strengths of red, green and blue pixels of the output signal, respectively, and R_(in), G_(in) and B_(in) represent the strengths of red, green and blue pixels of the input signal, respectively.

In the present design, the practical pixel arrangement and the input pixels are not in a one-to-one correspondence relation. Therefore, it needs to convert the practical pixel arrangement into virtual pixels, so as to be able to appraise the algorithm by RMS. The present design is to simulate how a practical pixel is converted into a virtual pixel based on a model established based on the subjective feelings of the human eye.

SUMMARY

Additional aspects and advantages of the present invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention.

The present design is a model design based on a virtual algorithm

The virtual algorithm processes an input signal by using a filter, can raise a relatively low physical resolution to a relatively high virtual resolution, and for different image types, shall adopt different filters as appropriate. The present design adopts that a sharpen border in an image is distinguished based on brightness borer decision, thereby processing the image by using different filters.

The virtual algorithm is a new type of image processing mode. With respect to a specific subpixel arrangement mode, the virtual algorithm can raise a relatively low physical resolution to a relatively high virtual resolution, optimize display effect and enhance the feelings of the human eye.

In order to judge the merits of the virtual algorithm, it needs to establish a set of evaluation standards. A common evaluation standard is to compare an input signal with an output signal, calculate the mean squared error of corresponding pixels. The smaller the mean squared error is, the higher it indicates the degree of reduction of the virtual algorithm for the original data is, and the better it indicates the virtual effect is.

In the pixel arrangement of the present design, practical pixels and traditional pixels are not in a one-to-one correspondence relation. Therefore, it needs to establish a human eye model to simulate the RGB value of the practical pixel at the position of the virtual pixel, and thus establish a correspondence relation between the traditional pixel and the virtual pixel. After the correspondence relation is established, the mean squared error between the traditional pixel and the virtual pixel can be calculated, to establish an algorithm evaluation standard.

The model established by the present design can be used to calculate the mean squared error between input data and output data and evaluate merits of the algorithm.

The present design simulates strength distribution of a single subpixel by establishing a lattice composed of a bivariate normal distribution.

The present design adjusts a dispersity of a single subpixel by adjusting a parameter σ² of a bivariate normal distribution.

The present design calculates a weight in a corresponding grid area by obtaining integral value of a single subpixel in different grid areas.

The present design simulates a strength distribution of a subpixel array by overlaying different subpixels at a same position.

The present design calculates the value of σ² under an optimum case through a limiting condition of a subpixel array.

The present design simulates subpixel arrays of different colors to obtain a final human eye model.

The human eye model of the present design should fit the subjective feeling of the human eye, and is adjusted and optimized continuously along with the actual situation.

The present disclosure provides a model establishing method based on a virtual algorithm, comprising: a) simulating a single subpixel; b) simulating a subpixel array of a single color; c) overlaying subpixel arrays of different colors; and d) deriving a virtual signal.

The present disclosure provides a model establishing system based on a virtual algorithm, comprising: a single subpixel simulating module configured to simulate a single subpixel; a subpixel array simulating module configured to simulate a subpixel array of a single color; a subpixel array overlaying module configured to overlay subpixel arrays of different colors; and a virtual signal obtaining module configured to derive a virtual signal.

BRIEF DESCRIPTION OF THE DRAWINGS

The preferred embodiments of the present invention will be detailed in conjunction with drawings. The above and other objects, characteristics and advantages of the present invention will become more apparent. In the drawings, same numbers designate units having same structures, and wherein:

FIG. 1 provides a new type of subpixel arrangement mode according to an embodiment of the present invention.

FIG. 2 provides a correspondence relation between an input signal, a practical pixel and a virtual pixel.

FIG. 3 shows red subpixels in practical pixels according to an embodiment of the present invention.

FIG. 4 provides a flow of a model establishing method based on a virtual algorithm according to an embodiment of the present invention.

FIG. 5 shows a simulation for a single subpixel according to an embodiment of the present invention.

FIGS. 6-8 show simulation results of subpixels when σ₁ and σ₂ have different values, respectively.

FIG. 9 shows a red subpixel array when taking a red subpixel as an example. FIG. 9A shows all red subpixels in the array. FIG. 9B shows a virtual pixel array taking a left side virtual pixel as an origin.

FIG. 10A and FIG. 10B provide that a limiting condition of σ² is determined by taking a red subpixel as an example according to an embodiment of the present invention.

FIG. 11 shows a curve graph of a relation between σ² and the strengths of both a left side virtual pixel and a right side virtual pixel according to an embodiment of the present invention.

FIG. 12A provides integral values, i.e. weight coefficients, of each grid obtained according to a selected parameter σ² by taking the left side virtual pixel in FIG. 9A as an origin; and FIG. 12B provides integral values, i.e. weight coefficients, of each grid when σ²=100 by taking the right side virtual pixel in FIG. 9A as an origin.

FIG. 13 provides simulating blue subpixel array according to an embodiment of the present invention. FIG. 13A shows all blue subpixels in the array. FIG. 13B shows integral values of each grid when σ²=100.

FIG. 14 provides simulating green subpixel array according to an embodiment of the present invention. FIG. 14A shows all green subpixels in the array. FIG. 14B shows integral values of each grid when σ²=100.

DETAILED DESCRIPTION

The present invention will be described fully below with reference to drawings showing embodiments of the present invention. However, the present invention can be implemented in many different forms, and should not be considered as limiting to the embodiments described herein. Instead, these embodiments are provided to make the present disclosure thorough and complete, and express fully the scope of the present invention to those skilled in the art. In the drawings, the components are exaggerated for clarity.

Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meanings as what those ordinary skilled in the art the present invention belongs to commonly understand. It should be further appreciated that the terms such as those defined in usual dictionaries should be construed as having meanings consistent with their meanings in the context of related art, and should not be construed in an ideal or extremely formalized sense, unless so defined expressly herein.

The present design simulates a single subpixel through a lattice composed of a bivariate normal distribution.

Through a limiting condition of a subpixel array, a normal distribution parameter σ² is determined.

Integration is conducted in different grid areas to derive weight coefficients of a subpixel at different spatial positions.

According to the selected parameter σ², eye models corresponding to RGB subpixel arrays are established, respectively.

FIG. 1 provides a new type of subpixel arrangement mode according to an embodiment of the present invention. This kind of subpixel arrangement mode can fully utilize a spatial arrangement of the three colors of red, blue and green, facilitating implementation of higher virtual resolution. Therein, the aspect ratio of each of the red, blue and green subpixels is 2:3, so three subpixels RBG constitute two pixels. A repeating group contains four pixels as shown in numbers {circle around (1)}{circle around (2)}{circle around (3)}{circle around (4)} in the figure.

FIG. 2 provides a correspondence relation between an input signal, a practical pixel and a virtual pixel.

The input signal is a traditional RGB signal, as shown in the first line, where the aspect ratio of each of the red, blue and green subpixels is 1:3, so three subpixels RBG constitute one pixel.

The practical pixel and the new type of subpixel arrangement mode shown in FIG. 1 are identical, as shown in the second line. Since each practical pixel does not have real RGB subpixels, for example, the pixels enclosed by a solid line in the second line only contain RB subpixels and do not contain G subpixel. Therefore, in order to show input RGB signals, it needs to utilize surrounding subpixels to commonly constitute virtual pixel containing such three components as RGB, for example, as shown in the third line.

How practical pixels are converted into virtual pixels will be described in conjunction with FIGS. 3-14 below.

FIG. 3 shows red subpixels in practical pixels according to an embodiment of the present invention.

For convenience of description, FIG. 3 only shows three virtual pixel positions by using dotting boxes. As shown in FIG. 3, taking an array composed of red subpixels as an example, each shown dotted box is a virtual pixel position, and is also the position of the corresponding input RGB signal. As shown in FIG. 3, two virtual pixel positions in the three virtual pixel positions shown with the dotted boxes in the figure do not have red subpixels. In order to achieve RGB display, it needs to calculate how many the red components of the two corresponding positions are. The model established by the present design is used to simulate how many each component such as the red component at each virtual pixel position “looks like”.

FIG. 4 provides a flow of a model establishing method based on a virtual algorithm according to an embodiment of the present invention.

As shown in FIG. 4, at step S401, a single subpixel is simulated.

At step S402, a subpixel array of a single color is simulated.

At step S403, subpixel arrays of different colors are overlaid.

At step S404, a virtual signal is finally derived.

FIG. 5 shows a simulation for a single subpixel according to an embodiment of the present invention.

As shown in the left part of FIG. 5, a single subpixel of a practical pixel is divided into 10×15 grids (since the aspect ratio of the subpixel of the practical pixel is 2:3). Each grid uses a bivariate independent normal distribution shown in formula 1 to simulate its strength value.

$\begin{matrix} {{f\left( {x,y} \right)} = {\frac{1}{2\pi \; \sigma_{1}\sigma_{2}}^{- {\frac{1}{2}{\lbrack{\frac{{({x - \mu_{1}})}^{2}}{\sigma_{1}^{2}} + \frac{{({x - \mu_{2}})}^{2}}{\sigma_{2}^{2}}}\rbrack}}}}} & (1) \end{matrix}$

Therein, μ₁, μ₂, σ₁ and σ₂ are the expectation values and standard deviations of x and y, respectively.

All points in a subpixel range are overlaid so as to obtain the simulated result of the subpixel, as shown in the right part of FIG. 5.

Degree of dispersion is a parameter representing the speed at which the strength of a subpixel model becomes smaller from the middle toward the distance. By adjusting σ² in formula (1), the degree of dispersion of the subpixel model can be adjusted.

FIGS. 6-8 show simulation results of subpixels when σ₁ and σ₂ have different values.

As shown in FIG. 6, there is shown the degree of dispersion of the subpixel when σ₁=σ₂=0.5.

As shown in FIG. 7, there is shown the degree of dispersion of the subpixel when σ₁=σ₂=5.

As shown in FIG. 8, there is shown the degree of dispersion of the subpixel when σ₁=σ₂=50.

It can be seen that, the greater σ² is, the greater the degree of dispersion of the subpixel model is, and the slower the varying speed of the strength of the virtual pixel is; and the smaller the degree of dispersion is, the faster the varying speed of the strength of the virtual pixel is. We need to select a suitable σ² according to practical needs.

Simulating subpixel array will be described below with reference to FIG. 9 to FIG. 12 by taking the red subpixel as an example.

FIG. 9 shows a red subpixel array when taking a red subpixel as an example.

FIG. 9A shows all red subpixels in the array.

In the red subpixel array of FIG. 9A, there is shown a repeating group composed of two virtual pixels (called “left side virtual pixel” and “right side virtual pixel”), i.e., those as shown in two dotted boxes in the figure. The strength distribution of a whole display screen can be obtained by obtaining red strengths of the two positions. For the left side virtual pixel, as shown in 9A, red subpixels R₁, R₃, R₄, R₆, R₇, R₈, R₁₀, R₁₁ and R₁₃ will influence a red strength value of the left side virtual pixel.

FIG. 9B shows a virtual pixel array taking a left side virtual pixel as an origin.

As shown in FIG. 9B, by taking a single subpixel model as an origin, a whole plane is divided into grid areas (what each grid is corresponding to is a virtual pixel), and a second integral of a single subpixel in different grids is calculated so as to determine the red strength value of the single subpixel.

FIG. 10A and FIG. 10B provide that a limiting condition of σ² is determined by taking a red subpixel as an example according to an embodiment of the present invention.

The shadow grids in FIG. 10A are subpixels having influence on the left side virtual pixel in FIG. 9A, and the shadow grids in FIG. 10B are subpixels having influence on the right side virtual pixel in FIG. 9A. When determining σ², it is assumed to be conducted under the condition that the red subpixels are all bright, and the strength values of the left virtual pixel and the right virtual pixel are as follows:

I _(left)=I_((0,2)) +I _((−1,1))+I _((1,1)) +I _((−2,0)) +I _((0,0)) +I _((2,0)) +I _((−1,1)) +I _(1,−1)) +I _((0,−2))

I _(right) =I _((−1,2)) +I _((1,2)) +I _((−2,1)) +I _((0,1)) +I _((2,1)) +I _((−1,0)) +I _((−2,−1)) +I _((0,−1)) +I _((2,−1)) +I _((−1,−2)) +I _((1,−2))

Wherein, I_((0,2)), I_((−1,1)), I_((1,1)), etc. are weight coefficients indicating influences of corresponding grids on the left side or right side virtual pixel. Because it is assumed that the red subpixels are all bright, the red strength value of each grid is all 255, and will be omitted in the above formulae.

Because the subjective feeling of human eyes looking at a display screen is a plane having uniformly distributed strengths, the strengths of the left side virtual pixel and the right side virtual pixel should be approximately equal. So a limiting condition is:

I_(left)=I_(right).

FIG. 11 shows a curve graph of a relation between σ² and the strengths of both a left side virtual pixel and a right side virtual pixel according to an embodiment of the present invention.

As shown in FIG. 11, with respect to σ² having a value of 25, 50, 100, 150, 200, 250 or 300, corresponding I_(left) and I_(right) are calculated, respectively. Those strength values marked with square points are values of I_(left) when σ² has a value of 25, 50, 100, 150, 200, 250 or 300; those strength values marked with circular points are values of I_(right) when σ² has a value of 25, 50, 100, 150, 200, 250 or 300; and those strength values marked with triangular points are values of the sum of I_(left) and I_(right) when σ² has a value of 25, 50, 100, 150, 200, 250 or 300.

It can be seen from FIG. 11 that, when σ² is 100, the strengths of the left side virtual pixel and the right side virtual pixel are approximately equal, and so σ²=100 is selected according to a limiting condition of I_(left)=I_(right).

FIG. 12A provides integral values, i.e. weight coefficients, of each grid obtained according to a selected parameter σ² by taking the left side virtual pixel in FIG. 9A as an origin; and FIG. 12B provides integral values, i.e. weight coefficients, of each grid when σ²=100 by taking the right side virtual pixel in FIG. 9A as an origin.

The subpixel array in FIG. 9 and the weight coefficients in FIG. 12 are of a centrosymmetric relation.

Integral values of every grid having effect on the virtual pixels are overlaid to derive the strengths of the left and right virtual pixels, i.e.:

R_(left) = 0.019 R₁ + 0.072 R₃ + 0.130 R₄ + 0.008 R₆ + 0.521 R₇ + 0.027 R₈ + 0.072 R₁₀ + 0.130 R₁₁ + 0.019 R₁₃; R_(right) = 0.006 R₁ + 0.011 R₂ + 0.004R₃ + 0.233 R₄ + 0.012R₅ + 0.162 R₇ + 0.291 R₈ + 0.004R₁₀ + 0.233 R₁₁ + 0.012 R₁₂ + 0.006 R₁₃ + 0.011 R₁₄. 

FIG. 13 provides simulating blue subpixel array according to an embodiment of the present invention.

FIG. 13A shows all blue subpixels in the array.

In the blue subpixel array of FIG. 13A, there are shown a repeating group composed of two virtual pixels (called “left side virtual pixel” and “right side virtual pixel”), i.e., those as shown by two dotted boxes in the figure.

FIG. 13B shows integral values of each grid when σ²=100.

Likewise, integral values of every grid are overlaid to derive the strengths of the left and right virtual pixels in the blue subpixel array, i.e.:

B_(left) = 0.016 B₁ + 0.003 B₂ + 0.033 B₃ + 0.193 B₄ + 0.431 B₆ + 0.074 B₇ + 0.033 B₈ + 0.193 B₉ + 0.016 B₁₁ + 0.003B₁₂; B_(right) = 0.006 B₁ + 0.011 B₂ + 0.233B₄ + 0.012B₅ + 0.004B₆ + 0.162 B₇ + 0.291 B₉ + 0.004 B₁₀ + 0.233 B₁₁ + 0.012 B₁₂. 

FIG. 14 provides simulating green subpixel array according to an embodiment of the present invention.

FIG. 14A shows all green subpixels in the array.

In the green subpixel array of FIG. 14A, there are shown a repeating group composed of two virtual pixels (called “left side virtual pixel” and “right side virtual pixel”), i.e., those as shown by two dotted boxes in the figure.

FIG. 14B shows integral values of each grid when σ²=100.

Likewise, integral values of every grid are overlaid to derive the strengths of the left and right virtual pixels in the green subpixel array, i.e.:

G_(left) = 0.011 G₁ + 0.006G₂ + 0.012 G₃ + 0.233G₄ + 0.004G₅ + 0.291 G₇ + 0.162 G₈ + 0.012 G₁₀ + 0.233 G₁₁ + 0.004 G₁₂ + 0.011G₁₃ + 0.006 G₁₄; G_(right) = 0.019 G₂ + 0.130 G₄ + 0.072G₅ + 0.027 G₇ + 0.521 G₈ + 0.008 G₉ + 0.130 G₁₁ + 0.072 G₁₂ + 0.019 G₁₄.

The RGB components are overlaid.

That is, R_(left), B_(left), G_(left) previously obtained according to different weights are placed into a pixel to obtain the left side virtual pixel.

R_(right), B_(right), G_(right) previously obtained according to different weights are placed into a pixel to obtain the right side virtual pixel.

Thus a human eye model is obtained. The human eye model should fit actual situations as far as possible, and is corrected at any time.

The above is the description for the present invention, and should not be considered as a limitation thereto. Although several exemplary embodiments of the present invention are described, those skilled in the art will readily understand, without departing from the novel teaching and advantages of the present invention, many modifications can be made to the exemplary embodiments,. Accordingly, all such modifications are intended to be included within the scope of the present invention defined by the claims. It should be understood that the above is the description for the present invention, and should not be considered limited to the disclosed particular embodiments, and modifications to the disclosed embodiments and other embodiments are intended to be included within the scope of the appended claims. The present invention is defined by the appended claims and their equivalents. 

1. A model establishing method based on a virtual algorithm, comprising: a) simulating a single subpixel; b) simulating a subpixel array of a single color; c) overlaying subpixel arrays of different colors; and d) deriving a virtual signal.
 2. The model establishing method according to claim 1, wherein step a) further comprises: dividing a single subpixel of a practical pixel into m×n grids; simulating each grid by using a bivariate normal distribution shown as follows; ${{f\left( {x,y} \right)} = {\frac{1}{2\pi \; \sigma_{1}\sigma_{2}}^{- {\frac{1}{2}{\lbrack{\frac{{({x - \mu_{1}})}^{2}}{\sigma_{1}^{2}} + \frac{{({x - \mu_{2}})}^{2}}{\sigma_{2}^{2}}}\rbrack}}}}};$ and overlaying all points within the range of the single subpixel to obtain a simulation result of the single subpixel, wherein, m is width, n is height, m:n=2:3, μ₁ and μ₂ are expectation values of x and y, respectively, and, σ₁ and σ₂ are standard deviations x and y, respectively.
 3. The model establishing method according to claim 2, wherein step b) further comprises: b1) determining a normal distribution parameter σ² through a limiting condition of the subpixel array.
 4. The model establishing method according to claim 3, wherein step b1) further comprises: establishing a subpixel array of a single color, which contains a repeating group composed of a left side virtual pixel and a right side virtual pixel; dividing a whole plane into a grid area in which each grid corresponds to a virtual pixel by using the left side virtual pixel as an origin, and calculating different integral values of the left side virtual pixel in different grids; dividing a whole plane into a grid area in which each grid corresponds to a virtual pixel by using the right side virtual pixel as an origin, and calculating different integral values of the right side virtual pixel in different grids; and under a condition that the subpixels of the single color are all bright, deriving a normal distribution parameter σ² according to a limiting condition that the strengths of the single color of the left side virtual pixel and the right side virtual pixel are equal.
 5. The model establishing method according to claim 4, wherein the strength of the single color of the left side virtual pixel is overlay of the strengths of the subpixels of the single color in different grids, having an effect on the left side virtual pixel, according to different integral values; and the strength of the single color of the right side virtual pixel is overlay of the strengths of the subpixels of the single color in different grids, having an effect on the right side virtual pixel, according to different integral values.
 6. The model establishing method according to claim 5, wherein step b) further comprises: b2) establishing a red subpixel array, which contains a repeating group composed of the left side virtual pixel and the right side virtual pixel; b3) according to the selected parameter σ², calculating the integral values of the left side virtual pixel and the right side virtual pixel in different grids to obtain different weight coefficients of the left side virtual pixel and the right side virtual pixel in different grid positions; b4) overlaying the strengths of the red subpixels in different grid positions, having an effect on the left side virtual pixel, according to different weight coefficients to obtain the strength of the red color of the left side virtual pixel, and overlaying the strengths of the red subpixels in different grid positions, having an effect on the right side virtual pixel, according to different weight coefficients to obtain the strength of the red color of the right side virtual pixel; b5) establishing a blue subpixel array, which contains a repeating group composed of the left side virtual pixel and the right side virtual pixel; b6) according to the selected parameter σ², calculating the integral values of the left side virtual pixel and the right side virtual pixel in different grids to obtain different weight coefficients of the left side virtual pixel and the right side virtual pixel in different grid positions; b7) overlaying the strengths of the blue subpixels in different grid positions, having an effect on the left side virtual pixel, according to different weight coefficients to obtain the strength of the blue color of the left side virtual pixel, and overlaying the strengths of the blue subpixels in different grid positions, having an effect on the right side virtual pixel, according to different weight coefficients to obtain the strength of the blue color of the right side virtual pixel; b8) establishing a green subpixel array, which contains a repeating group composed of the left side virtual pixel and the right side virtual pixel; b9) according to the selected parameter σ², calculating the integral values of the left side virtual pixel and the right side virtual pixel in different grids to obtain different weight coefficients of the left side virtual pixel and the right side virtual pixel in different grid positions; and b10) overlaying the strengths of the green subpixels in different grid positions, having an effect on the left side virtual pixel, according to different weight coefficients to obtain the strength of the green color of the left side virtual pixel, and overlaying the strengths of the green subpixels in different grid positions, having an effect on the right side virtual pixel, according to different weight coefficients to obtain the strength of the green color of the right side virtual pixel.
 7. The model establishing method according to claim 6, wherein step c) further comprises: placing red strength, blue strength and green strength of the left virtual pixel into a pixel to obtain the left virtual pixel; and placing red strength, blue strength and green strength of the right virtual pixel into a pixel to obtain the right virtual pixel.
 8. The model establishing method according to claim 7, wherein step d) comprises constituting the pixel subpixels obtained in step c) into a virtual signal.
 9. The model establishing method according to claim 8, wherein the normal distribution parameter σ² is equal to
 100. 10. The model establishing method according to claim 9, wherein m is equal to 10, and n is equal to
 15. 11. A model establishing system based on a virtual algorithm, comprising: a single subpixel simulating module configured to simulate a single subpixel; a subpixel array simulating module configured to simulate a subpixel array of a single color; a subpixel array overlaying module configured to overlay subpixel arrays of different colors; and a virtual signal obtaining module configured to derive a virtual signal.
 12. The model establishing system according to claim 11, wherein the single subpixel simulating module further comprises: a single subpixel dividing module configured to divide a single subpixel of a practical pixel into m×n grids; a normal distribution simulating module configured to simulate each grid divided by the single subpixel dividing module by using a bivariate normal distribution shown as follows; ${{f\left( {x,y} \right)} = {\frac{1}{2\pi \; \sigma_{1}\sigma_{2}}^{- {\frac{1}{2}{\lbrack{\frac{{({x - \mu_{1}})}^{2}}{\sigma_{1}^{2}} + \frac{{({x - \mu_{2}})}^{2}}{\sigma_{2}^{2}}}\rbrack}}}}};$ and an overlaying module configured to overlay all points within the range of the single subpixel simulated by the normal distribution simulating module to obtain a simulation result of the single subpixel, wherein, m is width, n is height, m:n=2:3, μ₁ and μ₂ are expectation values of x and y, respectively, and, σ₁ and σ₂ are standard deviations x and y, respectively.
 13. The model establishing system according to claim 12, wherein the subpixel array simulating module further comprises a normal distribution parameter determining module configured to determine a normal distribution parameter σ² through a limiting condition of the subpixel array.
 14. The model establishing system according to claim 13, wherein the normal distribution parameter determining module further comprises: a subpixel array of a single color establishing module configured to establish a subpixel array of a single color, which contains a repeating group composed of a left side virtual pixel and a right side virtual pixel; a left side virtual pixel integral module configured to divide a whole plane into a grid area in which each grid corresponds to a virtual pixel by using the left side virtual pixel as an origin, and calculating different integral values of the left side virtual pixel in different grids; a right side virtual pixel integral module configured to divide a whole plane into a grid area in which each grid corresponds to a virtual pixel by using the right side virtual pixel as an origin, and calculating different integral values of the right side virtual pixel in different grids; and a calculating module configured to, under a condition that the subpixels of the single color are all bright, calculate to derive a normal distribution parameter σ² according to a limiting condition that the strengths of the single color of the left side virtual pixel and the right side virtual pixel are equal.
 15. The model establishing system according to claim 14, wherein the strength of the single color of the left side virtual pixel is overlay of the strengths of the subpixels of the single color in different grids, having an effect on the left side virtual pixel, according to different integral values; and the strength of the single color of the right side virtual pixel is overlay of the strengths of the subpixels of the single color in different grids, having an effect on the right side virtual pixel, according to different integral values.
 16. The model establishing system according to claim 15, wherein the subpixel array simulating module further comprises: a red subpixel array establishing module configured to establish a red subpixel array, which contains a repeating group composed of the left side virtual pixel and the right side virtual pixel; a red subpixel array weight coefficient calculating module configured to, according to the selected parameter σ², calculate the integral values of the left side virtual pixel and the right side virtual pixel in different grids to obtain different weight coefficients of the left side virtual pixel and the right side virtual pixel in different grid positions; a red strength calculating module configured to overlay the strengths of the red subpixels in different grid positions, having an effect on the left side virtual pixel, according to different weight coefficients to obtain the strength of the red color of the left side virtual pixel, and overlaying the strengths of the red subpixels in different grid positions, having an effect on the right side virtual pixel, according to different weight coefficients to obtain the strength of the red color of the right side virtual pixel; a blue subpixel array establishing module configured to establish a blue subpixel array, which contains a repeating group composed of the left side virtual pixel and the right side virtual pixel; a blue subpixel array weight coefficient calculating module configured to, according to the selected parameter σ², calculate the integral values of the left side virtual pixel and the right side virtual pixel in different grids to obtain different weight coefficients of the left side virtual pixel and the right side virtual pixel in different grid positions; a blue strength calculating module configured to overlay the strengths of the blue subpixels in different grid positions, having an effect on the left side virtual pixel, according to different weight coefficients to obtain the strength of the blue color of the left side virtual pixel, and overlaying the strengths of the blue subpixels in different grid positions, having an effect on the right side virtual pixel, according to different weight coefficients to obtain the strength of the blue color of the right side virtual pixel; a green subpixel array establishing module configured to establish a green subpixel array, which contains a repeating group composed of the left side virtual pixel and the right side virtual pixel; a green subpixel array weight coefficient calculating module configured to, according to the selected parameter σ², calculate the integral values of the left side virtual pixel and the right side virtual pixel in different grids to obtain different weight coefficients of the left side virtual pixel and the right side virtual pixel in different grid positions; and a green strength calculating module configured to overlay the strengths of the green subpixels in different grid positions, having an effect on the left side virtual pixel, according to different weight coefficients to obtain the strength of the green color of the left side virtual pixel, and overlaying the strengths of the green subpixels in different grid positions, having an effect on the right side virtual pixel, according to different weight coefficients to obtain the strength of the green color of the right side virtual pixel.
 17. The model establishing system according to claim 16, wherein the subpixel array overlaying module further comprises: a left side virtual pixel synchronizing module configured to place red strength, blue strength and green strength of the left virtual pixel into a pixel to obtain the left virtual pixel; and a right side virtual pixel synchronizing module configured to place red strength, blue strength and green strength of the right virtual pixel into a pixel to obtain the right virtual pixel.
 18. The model establishing system according to claim 17, wherein the virtual signal obtaining module comprises constituting the virtual pixels obtained by the subpixel array overlaying module into a virtual signal.
 19. The model establishing system according to claim 18, wherein the normal distribution parameter σ² is equal to
 100. 20. The model establishing system according to claim 19, wherein m is equal to 10, and n is equal to
 15. 